EP1379421A4 - Building system, structure and method - Google Patents
Building system, structure and methodInfo
- Publication number
- EP1379421A4 EP1379421A4 EP02728443A EP02728443A EP1379421A4 EP 1379421 A4 EP1379421 A4 EP 1379421A4 EP 02728443 A EP02728443 A EP 02728443A EP 02728443 A EP02728443 A EP 02728443A EP 1379421 A4 EP1379421 A4 EP 1379421A4
- Authority
- EP
- European Patent Office
- Prior art keywords
- stmcture
- wall
- building
- foundation
- beams
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Classifications
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B7/00—Roofs; Roof construction with regard to insulation
- E04B7/08—Vaulted roofs
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/02—Structures consisting primarily of load-supporting, block-shaped, or slab-shaped elements
- E04B1/12—Structures consisting primarily of load-supporting, block-shaped, or slab-shaped elements the elements consisting of other material
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/18—Structures comprising elongated load-supporting parts, e.g. columns, girders, skeletons
- E04B1/28—Structures comprising elongated load-supporting parts, e.g. columns, girders, skeletons the supporting parts consisting of other material
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B7/00—Roofs; Roof construction with regard to insulation
- E04B7/02—Roofs; Roof construction with regard to insulation with plane sloping surfaces, e.g. saddle roofs
- E04B7/04—Roofs; Roof construction with regard to insulation with plane sloping surfaces, e.g. saddle roofs supported by horizontal beams or the equivalent resting on the walls
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B7/00—Roofs; Roof construction with regard to insulation
- E04B7/02—Roofs; Roof construction with regard to insulation with plane sloping surfaces, e.g. saddle roofs
- E04B7/06—Constructions of roof intersections or hipped ends
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B7/00—Roofs; Roof construction with regard to insulation
- E04B7/08—Vaulted roofs
- E04B7/10—Shell structures, e.g. of hyperbolic-parabolic shape; Grid-like formations acting as shell structures; Folded structures
- E04B7/105—Grid-like structures
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B7/00—Roofs; Roof construction with regard to insulation
- E04B7/20—Roofs consisting of self-supporting slabs, e.g. able to be loaded
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B2/00—Walls, e.g. partitions, for buildings; Wall construction with regard to insulation; Connections specially adapted to walls
- E04B2/84—Walls made by casting, pouring, or tamping in situ
- E04B2/86—Walls made by casting, pouring, or tamping in situ made in permanent forms
- E04B2/8652—Walls made by casting, pouring, or tamping in situ made in permanent forms with ties located in the joints of the forms
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/35—Extraordinary methods of construction, e.g. lift-slab, jack-block
- E04B2001/3583—Extraordinary methods of construction, e.g. lift-slab, jack-block using permanent tensioning means, e.g. cables or rods, to assemble or rigidify structures (not pre- or poststressing concrete), e.g. by tying them around the structure
Definitions
- This invention pertains to a modular building system, structure, and associated methodology.
- it relates to such a system, structure and methodology that feature an extremely simple, cost-effective, versatile, robust and intuitive field-assembly organization of interrelated components that can be interassembled quickly on a job site to create a large variety of different kinds of essentially frameless buildings, including residences, schools, warehouses, multistory structures, and other kinds of buildings.
- Components proposed by the present invention are readily combinable in a host of different architecturally unique, personal and interesting ways, and perform with one another in a finished structure with some remarkable load-handling performance, and stable endurance, capabilities.
- interlocking components are employed which are formed preferably from extruded (or pultruded) plastic material (hereinafter only referred to as extruded material), which components can even be produced (extruded and trimmed to appropriate sizes) strictly and easily on a job site itself, if so desired.
- extruded material plastic material
- components can even be produced (extruded and trimmed to appropriate sizes) strictly and easily on a job site itself, if so desired.
- the building system, structure and methodology of the instant invention present a number of unique facets and new advantages in the art of building construction, and some of the new areas of contribution of this invention rest at least in part upon a functional analogy to long-proven and admired hoop-and-stave structure in a barrel. More specifically, proposed according to the present invention is a construction wherein what are referred to herein as plural banding structures essentially fully, or nearly so, and from one point of view, circumsurround the structural elements forming the space occupied by a finished building, with closure structures, such as roof panels, wall elements, windows, doors, etc., supported as floating, elements that are held together and stabilized within the banding structures.
- wall structures that are formed, at least in part, from elongate, generally horizontal, vertically stacked, hollow, extruded, plastic beams which are designed and supported so as to operate as independent elements during various building loading conditions. These beams meet and engage one another through sliding interfaces between vertically next- adjacent beams, which interfaces allow the beams to bend independently, and thereby to adjust and position themselves longitudinally relative to one another. Opposite ends of these beams, while constrained against any gross motions, are nevertheless permitted slight migrations relative to one another to allow for such independent bending and sliding interfacial motion.
- a building which is made in accordance with the invention includes one of several different types of preferred foundation structures wherein perimeter members (in each case) are formed from defined-cross section extruded plastic material, such as a polyvinyl chloride (PVC) material of any appropriate choosing.
- PVC polyvinyl chloride
- One of these foundation types is especially suitable for subground-type supporting of a single-outside-wall-type building structure, such as a residence.
- This foundation structure as viewed in longitudinal cross section, is characterized by a kind of flattened V-shaped configuration.
- the superstructure support platform, so-to-speak, in this foundation lies substantially at ground- surface level.
- Another proposed foundation type is particularly suitable for ground- surface-level support of a double-outside-wall type building structure, such as a warehouse.
- This foundation structure has a somewhat flattened Z-shaped configuration as viewed in longitudinal cross section.
- a third type of proposed foundation is especially suited for the above- ground foundationing of the superstructure in a building, such as the residence mentioned above.
- This foundation structure as viewed in longitudinal cross section, has a rectangular configuration.
- the extruded components of the present invention act as the local forms for such concrete, and since these components are in ultimately to become part of the finished structure, traditional "form removal" is not a required activity.
- clusters of elongate, upright stabilizer bars rise therefrom to provide horizontal stabilization of overhead wall structures. The upper ends of these bars also act to anchor overhead roof structure directly to the foundation.
- the associated stabilizer bars extend downwardly through the foundation to anchor into the ground.
- the ground itself plays a role in forming what were referred to above as banding structures.
- wall beams are slid downwardly into place over the stabilizer bars, and are snapped together to form vertical stacks through tongue- and-groove, male/female nesting structures.
- Snapped-together nesting structures modestly lock vertically next-adjacent beams against vertical separation, while at the same time furnishing sliding interfaces between adjacent beams.
- reception channels are formed in vertically-extending trim pieces that define such building corners, or the sides of doors, windows, etc.
- the wall beams are hollow, and possess inner and outer, spaced, parallel faces, between which the stabilizer bars usually extend. If desired, exposed beam surfaces may be pre-profiled, colored, textured, etc. to provide an immediate, post-assembly finished look.
- This arrangement uniquely permits the beams in a wall structure to slide relative to one another longitudinally to deal with various kinds of loads that are delivered to buildings, thus to allow each beam to act somewhat as an independent beam element.
- roof structure which might typically be employed in a single- outside- walled building, such as a residence, includes angularly intersecting, elongate, linear rafters which rise from spaced, generally parallel wall structures toward an elevated ridge. These rafters, once in place, are poised to receive slidably introduced roof panels which may take different forms.
- One such form disclosed herein is solid and light-opaque in nature.
- Another is built with translucency or transparency. All, once in place, can shift slightly relative to one another to accommodate various building loading conditions.
- the rafters in such roof structure cooperate with the stabilizer bars to which they are effectively anchored, to form a completion over the upper reaches of a building, of the earlier-mentioned banding structures.
- Anchoring of the roof structure to the stabilizer bars effectively anchors the roof structure to the foundation and the ground.
- Vertical downward loads that are borne by a roof structure in accordance with the present invention create compressive loads downwardly through the wall beams to the foundation and the ground.
- Vertical upwardly directed loads on a roof structure such as the very serious kinds of loads experienced during high wind and storm conditions, are uniquely borne in tension through the stabilizer bars, which deliver load directly from the roof structure to the foundation.
- Another proposed roof structure is very much like the first one just outlined above, except that the rafter structure employed does not include a ridge-line intersection angle. Rather, it features, preferably, elongate, continuous arched rafters which are retained in an appropriate arched condition via compression attachments provided adjacent the rafters' respective opposite ends near the tops of spaced walls.
- a third roof structure type differs from the one just mentioned above by featuring elongate, continuous arched rafters which are held in arched conditions by elongate tension lines coupled to, and extending between, the rafters' opposite ends.
- a fourth type of roof structure proposed by the present invention is an arched, cross-cable trussed structure which has special utility in connection with spanning broad areas between widely spaced wall structures.
- Fig. 1 is a fragmentary, isometric, simplified diagram of a residence, or residence structure, which has been constructed in accordance with the present invention.
- Fig. 2 is a schematic, stick-figure drawing, taken as if from one end, such as the near gabled end, of the residence of Fig. 1, generally showing the several building components which act collaboratively as banding structure, or structures, in this residence.
- Fig. 3 is an isometric, isolated and fragmented view of several elongate, slidably interengaged wall beams which are present in the residence of Fig. 1, and which are constructed in accordance with the present invention.
- Fig. 4 is a simplified fragmentary, and somewhat stick-figure view isolating and showing the below-ground foundation, and the plural clusters of upright, elongate stabilizer bars, which are employed in the residence of Fig. 1.
- Fig. 5 a view which has somewhat the character of Fig. 3 ⁇ shows, in isometric view, slidably supported panels that form part of the roof structure in the residence of Fig. 1.
- Fig. 6 is a fragmentary, schematic elevation further showing wall beams that are provided in the residence of Fig. 1.
- Fig. 7 is a fragmentary plan-illustration-section of a comer of the residence of Fig. 1, showing how comer trim stmcture, and nearby stabilizer bars, accommodate sliding relative motions between wall beams which are employed in the residence of Fig. 1.
- Fig. 8 is a stylized fragmentary plan view illustrating generally one non- gabled side of the residence of Fig. 1.
- Fig. 9 is a larger-scale, more detailed plan-cross-section view of the same side of the residence pictured in Fig. 8.
- Fig. 10 is a fragmentary, vertical section looking inwardly from the left side of the near, gabled end of the residence of Fig. 1.
- Fig. 11 is a smaller-scale, fragmentary, isometric view picturing much the same structure illustrated in Fig. 10.
- Fig. 12 is an enlarged, fragmentary detail taken near the upper region of Fig. 10.
- Fig. 13 is an enlarged, fragmentary detail taken near the lower region of Fig. 1.
- Figs. 14 and 15, taken along with Fig. 13, illustrate a leveling system which is employed in the residence of Fig. 1.
- This leveling system (which is actually a perimeter-distributed system) is present, in part, generally in the region in Fig. 13 which is bracketed by the two curved arrows labeled 14, 15 - 14, 15.
- Figs. 16A and 17 illustrate the configurations of several components that form portions of roof and rafter structure present in the residence of Fig. 1.
- Fig. 16A is an exploded view, and Fig. 17, a cross section taken generally along the line 17-17 in Fig. 16A.
- Fig. 16B is a simplified schematic drawing which illustrates two different types of arched roof structures made up of components quite similar to those shown in Figs. 16A, 17.
- Fig. 18 is a view presenting, on roughly the same exposition level as that which is employed in Fig. 12, details of construction that exist at the roof ridge in the residence of Fig. 1.
- Fig. 19 is a fragmentary, cross-sectional elevation illustrating a portion of a building, somewhat like the residence of Fig. 1, which has two stories.
- Fig. 20 is a fragmentary, cross-sectional detail of an above-ground foundation made in accordance with the present invention.
- Fig. 21 is a simplified, fragmentary, isometric view showing a large double- outside-walled building stmcture, including a broad arched roof structure, built in accordance with the present invention.
- Figs. 22-25, inclusive (appearing on two plates of drawings) present various different views of components that make up the arched roof stmcture pictured in Fig. 21.
- Fig. 26 is a fragmentary detail illustrating how the roof structure of Fig. 21 is anchored near the top of exterior wall structure.
- Fig. 27 is a fragmentary detail illustrating an above-ground foundation structure which is employed in the building of Fig. 1.
- Fig. 28 is a block/schematic diagram illustrating on-job-site extmsion of plastic building components in accordance with one manner of practicing the methodology of the present invention.
- building structure 30 takes the form generally of a single-story residence, illustrated only in very simplified form in this figure.
- Residence 30 includes one of the two previously-mentioned forms of below-ground foundation stmcture 32 constructed in accordance with the invention. Seated on top of foundation 32, and rising therefrom, are single-layer, outside wall stmctures, or walls, such as the two shown generally at 34, 36. These two walls are disposed generally orthogonally with respect to one another, with wall 34 being one of the two outside rectangular-perimeter walls, and wall 36 being one of the two gabled walls.
- a ridged, roof stmcture 38 Seated on top of these walls is a ridged, roof stmcture 38 which includes, generally speaking, two broad expanses 38a, 38b, separated angularly by a ridge structure 39. Shown generally by dashed lines, such as the several lines appearing at 40, are groups, or clusters, of upright, elongate stabilizer bars, the specific stmctures of which will be described more fully shortly.
- these stabilizer bars which are also referred to herein as stabilizer or stabilizing structure, as load- transmitting bars, and as tension elements, extend through foundation 32 and into the ground.
- the stabilizer bars rise from the foundation, according to an important feature of the invention, to provide anchoring points directly for roof structure 38.
- These stabilizer bars in addition to providing direct anchoring to the foundation and ground for roof stmcture 38, also act to stabilize generally the vertical and lateral positions of beam elements, or beams, soon to be more fully described, which make up much of the exterior walls in residence 30.
- Each of these walls is formed from a plurality of different elements which include plural, elongate (different length) hollow beam elements, or beams, such as the beams shown generally at 42, 44, 45 in walls 34, 36, respectively.
- the beams are stacked one upon another, engaging through what are referred to herein as co-contacting slide, or sliding, surfaces, or interfaces formed generally as male/female, tongue-and-groove substructures, also referred to herein as nesting structures.
- co-contacting slide, or sliding, surfaces, or interfaces formed generally as male/female, tongue-and-groove substructures, also referred to herein as nesting structures.
- each wall beam is permitted to respond to loading very much as an independent flexing and bending beam element, with such independent flexing and bending leading to the type of relative motion mentioned.
- each wall beam is permitted longitudinal relative motion of up to about ' ⁇ -inches.
- each end is received in channellike structure furnished in an appropriate upright trim piece, and it is within this channel stmcture that the clearance for such motion is provided.
- rafters Within residence 30, and generally associated with the several upright clusters 40 of stabilizer bars that are distributed along each wall, and forming portions of roof stmcture 38, are rafters, or rafter structures, like those shown generally at 50, 52. Also included in roof structure 38, as pictured in Fig. 1, are plural, elongate panels, such as panels 56, 58, 60, 62, which are shown on the near, right side of the roof structure in Fig. 1. As will become more fully apparent, each of these panels resides effectively slidably between a pair of rafters. Just as was described for the wall beams, the roof panels are also permitted a certain amount of relative motion, generally as indicated by double-ended linear arrow 64 in Fig. 1.
- Fig. 1 the moved positions which are shown for wall beams and roof panels are highly exaggerated simply to point out and emphasize the important relative-motion quality of a building structure made in accordance with the invention.
- Figs. 3, 4, and 5 help further to illustrate generally the respective structural organizations, and relative motions (exaggerated) discussed so far above.
- Fig. 3 for example, conditions of the wall beams can clearly be seen.
- hollow natures of these beams as well as the male/female, tongue-and-groove characteristics of the beam nesting structures. Hollowness in the beams furnishes, among other things, space for the placement of insulation, and mns for electrical and plumbing structure.
- Fig. 4 shows a bit more fully the various clusters of upright elongate stabilizer bars.
- the stabilizer bars are organized into clusters of (a) three bars adjacent the comers of residence 30, and (b), intermediate the comers, pairs of such bars. More will be said about these organizations below.
- residence 30 Before turning further attention now to details of constmction of various building components in residence 30, it should be noted again that most of its components are formed, in accordance with this invention, of extruded plastic material. These components have specific configurations and forms which allow for highly intuitive, and very simple, snap, slide and fit-together construction of an entire building on a job site, with there being little requirement for skilled labor or special tools. The detailed description which will follow now with respect to certain specific components will make this characteristic of building structure as proposed by the present invention very apparent.
- foundation 32 is made up of elongate extruded plastic components which have a kind of flattened V-shaped configuration, as can be seen on the right lower side of Fig. 2.
- the upper support surface of this foundation essentially sits at ground level which, in Fig. 2 at least with respect to foundation 32, is represented by dash- triple-dot line 66.
- stmcture 40 Rising upwardly from foundation 32, at the right side of Fig. 2, is stabilizer bar stmcture 40.
- bar stmcture 40 At the upper end of bar stmcture 40 is a small block 68 which represents a load-transmitting connection to the right end of previously-mentioned rafter structure 50.
- the left end of stmcture 50 joins with the right end of previously-mentioned rafter structure 52 through a connection shown at 70 which exists at the angular ridge 54 previously mentioned in residence 30.
- the left end of rafter stmcture 52 is connected at 72 for load transmission downwardly through the foundation and into the ground through another stabilizer bar stmcture which is also designated in Fig. 2 with reference numeral 40.
- foundation 32 is essentially cross-sectionally the same at all locations.
- the left side of the schematic building pictured here is illustrated with another form of foundation which will be discussed shortly. Ignoring for the moment that a different specific foundation structure is represented at the lower left comer of Fig. 2, and assuming for a moment that the same foundation structure 32 were there represented, a connection with and through the underlying ground is established from the lower ends of the stabilizer bars through foundation 32, and then through ground structure which bridges between opposite sides of the foundation components.
- Such bridging ground structure is represented by dash-double-dot line 74 in Fig. 2.
- This banding structure includes stabilizer bar stmcture 40, rafter stmctures 50, 52, load-bearing and transmitting connections 68, 70, 72, foundation stmcture 32, and bridging ground stmcture 74.
- This representative banding structure which appears in the plane of Fig. 2 will be seen, on referring back to Fig. 1, to be repeated essentially through the length of building stmcture 30 as such is measured along a line following ridge stmcture 54.
- Fig. 2 appearing near the upper left-side of the figure, is a repositioned version of previously-mentioned, double-ended straight arrow 64 which represents the principal direction of modest relative motion that is permitted to panels that make up the roof stmcture.
- this relative motion in roof panels takes place along a line, or lines, which lie in the plane of Fig. 2 - a vertical plane. These lines are inclined relative to the horizontal, as dictated by the slope of the roof structure.
- Pointed to at the left side in Fig. 2, generally by a curved arrow 76, are two circled symbols which reflect vector directions, or vectors, into and out of the plane Fig. 2.
- FIG. 2 Illustrated generally at 84 at the lower right side of Fig. 2 is an alternative above-ground foundation which is employed according to another modification of the invention. Details of this foundation will be discussed later herein, but one can see in Fig. 2 that foundation 84 is one that is designed to sit above the ground surface, such ground surface being represented by dash-double-dot line 86 in Fig. 2.
- FIG. 2 Curving overhead the elements so far described in Fig. 2 is an alternative, arched, broad-expanse roof structure 88 which is uniquely offered by the present invention. Opposite ends of structure 88 are shown terminating with load- transmitting anchor points 90, 92 which, in Fig. 2, are functional analogies to previously-mentioned load-transmitting anchor points 72, 68, respectively. These anchor points, in a building stmcture employing a roof stmcture like stmcture 88, are effectively anchored through the building foundation structure to the ground via stabilizer bar structure, such as that previously discussed herein. The specific make-up (several different modifications) of arched roof stmcture 88 will be described later herein.
- closure panels which can, as indicated by double-ended curved arrow 94 in Fig. 2, shift with slight relative motion back and forth with respect to neighboring structure.
- the left ends of beams 42 are received within an accommodating channel space 98a, furnished in a vertical corner trim piece 98.
- the adjacent ends of beams 42 can shift modestly longitudinally relative to one another along their long axes with a motion range R.
- Dashed lines which are pictured in Fig. 6 at 42A show exaggerated deformations that occur in beams 42 when something, for example, a vertical load, causes downward bending of these wall beams to produce slight upwardly facing concavities in the upward surfaces of these beams.
- Such bending will normally occur well within the elastic limits of the beams, and so when whatever load which has been applied that produces the deformation thus described in Fig. 6 is removed, the beams will essentially return to the conditions shown for the beams in solid lines in Fig. 6, though not necessarily with the opposite ends of the beams still precisely vertically aligned with one another.
- such a deformation accommodated by independent beam motion relative to adjacent beams also in bending, may from time to time cause the opposite ends of vertically stacked beams to assume relative different vertical dispositions with respect to one another.
- the amount of relative motion thus permitted in and promoted by the independent wall beams is an important performance feature of the present invention which uniquely allows these beams to sustain loads in very responsive and fully recoverable manners.
- FIG. 8 there is presented in a schematic plan view a more detailed representation of the plan layout of the groups of stabilizer bars numbered 40 and shown very generally in Figs. 1 and 2.
- Fig. 8 several of the groupings of stabilizer bars are thus represented by general reference designators 40, and one will see that there are, fundamentally, two different characteristics of stabilizer bar groupings.
- FIG. 1 Referring back for a moment to Fig. 1 to describe a little more particularly a visual relationship which is intended to exist between what is shown in Fig. 1 and what is shown in Fig. 8, illustrated in Fig. 1 at 30A, 30B, 30C, 30D, 30E, 30F and 30G are what can be thought of as seven different linearly distributed sections in previously-mentioned wall 34.
- the layout pictured in Fig. 8 is almost an exact match with respect to these seven wall sections, except that, in Fig. 8, section 30F, which contains a window that can be seen in Fig. 1, has been omitted and fragmented out of Fig. 8.
- Sections 30A, 30C, 30E and 30G are simply entirely made up, from foundation to roof stmcture, from a vertical stack of elongate, horizontal beams.
- Sections 30B, 30F include both stacks of horizontally extending beams, and a window.
- Section 30D includes a certain number of horizontal beams, but principally includes a door previously designated 48. Where regions of adjacent wall sections are uninterrupted by a window or a door, etc., beam structure is essentially unbroken and continuous from section to section. This can be seen especially in Fig. 1 in sections 30A-30C, and 30E-30G.
- Fig. 1 the organization of groups of stabilizer bars which are associated with wall 34, there are eight such groupings. All eight are shown generally in Fig. 1. In Fig. 8, however, only six of these groups are pictured ⁇ the missing two groups being associated with opposite, lateral sides of fragmented-away wall section 30F. As can be seen in Fig. 8, among these eight group of stabilizer bars, the two corner groups include three stabilizer bars each, and in each other group, there are just two such bars.
- the spacing (Si) between the long axes of next-adjacent bars is about 80-mm, and between bars in each group of two bars, the lateral spacing (S 2 ) between longitudinal axes is about 160-mm.
- the nominal center-to-center distance (D) between adjacent groups is about 1200-mm.
- each stabilizer bar is actually made up of a plurality of end-to-end disposed elongate bars which are joined through turnbuckle-like stmcture which allows for lengthening and shortening of the overall effective upright lengths of the bars.
- Appropriate threading or similar connection method is provided, as will also become more fully apparent, at locations where threaded connections to the bars are furnished for various purposes.
- the lower ends of the bars are firmly anchored, as will also shortly be described, through foundation structure 32 and into the underlying ground.
- the upper ends of the bars are employed with auxiliary structure, still-to-be described, which helps to stabilize the upper regions of the walls, and also to anchor, directly to the foundation, the roof and rafter stmcture. It should be recalled from a discussion that was presented earlier with respect particularly to Fig. 2, that the individual stabilizer bars, in the several groups of bars now distributed around the perimeter of residence 30, form portions of the important banding structures in residence 30.
- FIG. 9 which is on a larger scale than that employed in Fig. 8, essentially shows the same plan layout pictured in Fig. 8. Most especially, shown in this figure are actual fragmentary cross sections of specific components that are employed in wall 34, with the exception of wall section 30F which has been fragmented away. Progressing upwardly from the lower portion of Fig.
- wall section 30A which is made up entirely of beams 42
- wall section 30B which includes a combination of beams 42 and window 46, with lateral sides of this window being defined by trim pieces 100, 102
- wall section 30C which is made up substantially entirely of beams 42
- wall section 30D which contains principally previously-mentioned door structure 48, opposite lateral sides of the wall structure being defined by trim pieces 104, 106 (which are very much like trim pieces 100, 102);
- wall section 30E principally made up of beams 42;
- wall section 30F (appearing only in Fig.
- wall section 30G which made up principally entirely of beams 42.
- the upper extremity of wall section 30G in Fig. 9 has its stacked beams' ends stabilized in a channel 108a in a corner trim piece 108 which is substantially a duplicate of previously-mentioned trim piece 98.
- 100, 102, 104, 106, 108 are formed from extruded plastic material to have the respective cross-sectional appearances clearly illustrated in that figure, and are cut off to have the appropriate lengths to fit appropriately within wall 34.
- the small circles which one sees distributed essentially along the length of wall 34 in Fig. 9 represent (a) the individual stabilizer bars previously mentioned, and (b) the toleranced clearance holes provided appropriately for them. Details in Fig. 9 of how the bars' circumferences are afforded clearance spaces within the cross sections of the various components through which the bars pass is not specifically shown in Fig.
- foundation stmcture 32 herein is made up principally of two differently cross-sectioned components including a lower component 32a and an upper component 32b. Components 32a, 32b are snapped together to produce collectively what was referred to earlier herein as a flattened V-like cross-sectional configuration.
- upper component 32b includes a generally horizontal shoulder 32d which resides essentially at ground level 66. Rising upwardly from shoulder 32d is a male projection portion 32e which, as will shortly be explained, receives a complementarily fitting, downwardly directed female portion formed on the underside of a wall beam.
- male/female components define the full equivalent, at the foundation level, of the nesting stmctures which define the snap- together, sliding facial interfaces between vertically stacked, next-adjacent wall beams.
- the undivided stabilizer bar pictured here at 41 includes, as illustrated, three components 41a, 41b, 41c which are elongate and longitudinally aligned to form an upstanding structure extending from within the ground below the foundation stmcture, upwardly to a considerable height above the foundation stmcture.
- components 41a, 41b, 41c Suitably provided at the appropriate locations within foundation components 32a, 32b are clearance bores that afford free vertical passage for the components that make up bar 41.
- These clearance bases are positioned generally as indicated by the patterns pictured therefor in Figs. 8 and 9.
- stabilizer bar component 41a extends completely through foundation component 32a, downwardly therefrom into the ground and upwardly therefrom into the region which enters the lower part of foundation component 32b. It is with respect to adjustments shortly to be described that can be performed with respect to stabilizer bar component 41a that a unique leveling operation can be carried out in accordance with the present invention.
- a unique leveling operation can be carried out in accordance with the present invention.
- each stabilizer bar coupled threadedly to the upper end of bar component 41a is a turnbuckle-like sleeve which is component 41b. The upper portion of sleeve threadedly receives the lower end of stabilizer bar component 41c. Selective rotation, as desired, of sleeve 41b effectively shortens or lengthens the overall length of bar 41.
- a specially shaped adjustment nut 110 which has the configuration clearly pictured for it in Fig. 15. Lugs 110a which extend upwardly through a suitable accommodating bore 112 provided in foundation component 32a center this nut, and therefore, stabilizer bar component 41a, with respect to opening 112, with opening 112 affording vertical downward access to nut 110 by a special adjustment tool shown at 114 in Figs. 14 and 15.
- the appropriate shape of the lower end of tool 114 is especially well illustrated in Fig.
- the appropriate vertical lengths of the stabilizer bars above the foundation is adjusted through operation of tumbuckle components like component 41b.
- Figs. 10 and 13 what is illustrated in Figs. 10 and 13 is an arrangement wherein the lower portion of residence 30, and particularly the foundation stmcture in that residence, is load-bridged not only by the ground which extends between and receives the lower ends of the stabilizer bars, but also by the floor stmcture which is caught on the floor connection portion 32f just mentioned.
- This bridging condition plays a role in the previously-mentioned banding stmcture.
- Extending upwardly from foundation stmcture 32 in the particular portion of residence 30 which is illustrated in Figs. 10, 11 and 13, are plural, vertically- stacked wall beams 42. Each of these beams has a cross-sectional configuration like that which is clearly pictured especially in Fig.
- the two, gabled, end walls in residence 30 are formed according to the invention in much the same manner that has just been described so far for wall 34. Appropriate adaptations are, of course, made along the slopes of the gabled stmctures of these walls.
- finishing trim components Shown generally at 120 in Fig. 10, and also in Fig. 11, are finishing trim components which are snapped downwardly into place along the upper reaches of the uppermost wall beams, intermediate the locations of the groups of stabilizer bars.
- These finishing trim pieces have upper surface angularity, clearly pictured in Fig. 10, which is suitable for the angle designed for the roof structure in residence 30, and the trim pieces are shaped on their undersides essentially to have the same kind of female structure which has been discussed so far in relation to the wall beams. With these upper finishing trim pieces in place, it will be apparent that they fit onto the upper wall beams through sliding interfaces which are very much like those that exist between vertically stacked and adjacent wall beams.
- Figs. 10 and 12 structure which exists specifically at the locations of the upper extremities of the stabilizer bars, resting as shown on spanner reaches 42b within the uppermost wall beams are anchoring plates such as plate 122. These plates each have a length, measured normal to the planes of Figs. 10 and 12 which is sufficient to bridge the two adjacent stabilizer bars in each group of two such bars. Appropriate clearance bores are provided in these plates to receive and slide downwardly over the upper extremities of such two, next-laterally-adjacent bars.
- similar plates not specifically shown, are included which are right-angle plates, and which are configured to receive, clearingly, the upper ends of the three stabilizer bars which form a cluster of bars at those locations.
- stabilizer bar components 41c which are the very ends that extend through these anchoring plates, are threaded, and nuts, such as nut 124, are screwed down finger tight onto the stabilizer bar components 41c to bear downwardly modestly on anchor plates, like plate 122.
- This finger- tight connection places a very modest amount of preliminary tension in the stabilizer bars.
- reception hoops 126 which are (a) generally circular, (b) angled as shown in Figs.
- tubular components 10 and 12 to accommodate the angle of the planes of the roof stmcture, and (c) fitted with a short section of cylindrical metal tubing 128 which extends to opposite sides of what can be thought of as the inclined plane occupied by hoop 126.
- tubular components can, of course, have other perimeter configurations, but herein, these configurations are circular.
- each rafter stmcture herein essentially takes the form of an elongate extmded component, such as that shown at 130.
- Each component 130 has an outer end that is slidably fit onto the upwardly directed portion of differed tubular components 128.
- Fig. 16A components 130, 128 are shown in an exploded and relatively disconnected set of conditions.
- Fig. 12 the components are shown partly assembled, and the downward arrow which appears at 132 in Fig. 12 simply demonstrates the direction of fitting of component 130 onto component 128.
- component 130 is shown fully in position relative to hoop 126.
- Figs. 10 and 12 Shown at 134 in Figs. 10 and 12 are components which have a cross section that substantially matches that of component 130, and which axially align therewith on and along tubular component 128 to extend laterally outwardly and slightly downwardly from the upper extremities of the wall stmctures.
- a ridge stmcture component which includes angular plate structure 136a including a central upright plate 136b, and joined to this central plate, two slightly downwardly angled tubular members 136c.
- Members 136c have the same cross-sectional cylindrical configuration as earlier- described tubular member 128.
- tubular members 136c extend into the upper, open ends of structural members 130.
- this connection has not yet taken place. When it has taken place, and when the counterpart rafter structure that extends to the right of component 136 in Fig.
- rafter stmcture extends across one region of the roof structure in residence 30 between a pair of stabilizer bars on either side of the residence.
- Rafter structures assembled from components like those just discussed with reference to Figs. 10, 12 and 16A are completed at all appropriate locations along the lengths of the rectangular wall, like wall 34, and with these components in place, what can be thought of as the rafter framework stmcture of the roof structure is ready to receive closure panels, such as previously-mentioned panels 56, 58, 60, 62.
- roof panels like those which have just been mentioned can take a number of different forms, including panels which are completely light and air opaque, panels which include windows, and other sorts of panels which one can imagine. These panels are appropriately formed with perimeter stmcture that allows them to be slid into contained positions between adjacent rafter structures that extend downwardly from the ridge in residence 30 toward the lateral wall structures.
- Fig. 17, which illustrates the cross-sectional configuration of extmded component 130 clearly illustrates how two different kinds of roof panels, shown generally at 138, 140, can be equipped with appropriate extruded perimeter structures to fit slidably onto the opposite lateral sides of rafter component 130.
- Panel stmcture 138 herein takes the form of a light- transmissive window stmcture
- panel 140 takes the form of a light and air opaque closure stmcture.
- Fig. 18 illustrates very generally additional stmcture which can be employed advantageously to finish off the ridge stmcture region in residence 30.
- an adjustable vent structure 142 which includes a rockable panel 142a which accommodates venting through appropriate air vent spaces furnished, such as the space shown generally at 144, (b) a portion 146 of a fire-suppression plumbing system which is disposed within the residence extending along (in the illustration now being given) the ridge stmcture, (c) an insect-blocking but air-passing screen structure 148 which is perched as a canopy over the air vent region, and (d) a solid canopy 150 which overrides structure 148 with laterally-opposite edges attached to angle anchor structures such as those shown at 152.
- FIG. 16B indicated generally at 153 is one form of an arched roof structure proposed according to the present invention.
- structure 153 includes plural elongate arched rafter structures, such as that represented at 153a by a single curved line.
- This rafter stmcture is essentially constmcted from the same kinds of components, such as components 126, 128, 130, previously discussed, wherein the component which is a counterpart of previously-mentioned component 130 is one elongate, unbroken element which has no angularity or ridge stmcture, and which extends across a span in a building, such as residence 30, between the pair of spaced walls, such as between the two rectangular walls present in residence 30.
- the opposite ends of rafter structure 153a are supported through compression attachment components 154, 155 that reside at the upper extremities of walls at the locations shown, for example, in Figs. 10 and 12, where retainer hoop 126 is shown.
- Closure panels are slidably received at the edges of the components in the rafter stmctures, and form an appropriate matching arch simply by bending as they are introduced slidably into and along the receiving structures in the rafter components.
- Fig. 16B can also be employed, and is now so employed, to describe still another form of arched roof and rafter stmcture suitable for incorporation, for example, in a building such as residence 30.
- this form of roof and rafter stmcture is that, instead of attaching components 154, 155 acting as compression attachment components for the opposite ends of a rafter structure, each elongate rafter stmcture is held in the appropriate arched configuration by an elongate tensed spanner line, such as that shown by dash-double-dot line 157 in Fig. 16B.
- an elongate tensed spanner line such as that shown by dash-double-dot line 157 in Fig. 16B.
- a component 158 which is essentially the same in construction as previously-mentioned upper foundation component 32b illustrated in Figs. 10 and 13.
- Component 158 is snap-fitted at the appropriate height onto the upper male nesting portion of a wall beam which in Fig. 19 is also given reference numeral 42. Snap-fit onto the upper male nesting portion of component 158 in Fig. 19 is the lower female nesting portion of an overhead wall beam, also designated 42.
- the inward-turned ledge portion 158a in component 158 which is like previously-mentioned portion 32f in foundation component 32b, is positioned to receive downwardly placed floor structure shown generally at 160 in Fig. 19.
- FIG. 20 illustrates in a more detailed fashion previously-mentioned alternative foundation stmcture 84 which was first mentioned with respect to earlier-discussed Fig. 2 herein.
- Foundation stmcture 84 as here pictured includes three components 84a, 84b, 84c which are snap-fitted nestingly in vertical disposition relative to one another.
- Components 84a, 84b are the same in construction and are effectively the same in cross-sectional configuration as previously-described components 32b and 158.
- Component 84c forms a base component in foundation stmcture 84 and has a cross-sectional configuration which for it is also clearly pictured in Fig. 20.
- Component 84c like components 84a, 84b is extmded from plastic material, such as PVC material. Rising upwardly from upper foundation component 84b is a wall beam 42 which is snap-fitted onto this component in the manner previously described for beams 42 in residence 30.
- stabilizer bars such as the bar shown at 162 extends downwardly through components 84a, 84b, and is secured against vertical retraction by a nut 164 which is essentially the same in constmction as previously-described nut 110.
- Floor and other lower structure in a building employing foundation stmcture 84 is generally pointed to at 166 in Fig. 20, but details of this floor stmcture do not form part of the present invention. What should be mentioned however, is that lateral load-bearing between spaced components in foundation stmcture 84 is borne through floor components which latch onto the foundation components such as is illustrated generally at 168 in Fig. 20.
- a base expanse 170 Disposed above base expanse 170, and directly resting on this expanse, according to what is pictured in Fig. 20, is a large water bladder 172 which can perform a number of functions in a building employing foundation structure 84. These functions include introducing substantial weight adjacent the base of a building to stabilize the overall stmcture with respect to its position on the ground.
- Transversely spanning spaced locations in foundation structure 84 are plural beams, such as the beam shown generally at 174 in Fig. 20. These transverse beams play a role in laterally stabilizing the relative positions of spaced portions of foundation structure 84.
- Wall stmctures 182, 184 are spanned by an overhead curved/arched roof structure 186. Focusing attention especially for a moment on Figs. 22, 26 and 27, and discussing wall structures 182, 184 with specific reference to wall stmcture 184, here one can see that this wall stmcture includes inner and outer portions 184a, 184b, respectively, each of which has much the same individual construction as previously described wall structure 34.
- wall structure 184 is specifically shown schematically at 82 in Fig. 2, and can be seen to have great similarity to previously-described foundation stmcture 32.
- This foundation structure has a somewhat flattened Z-shaped configuration on its opposite sides, with this configuration essentially resulting from the vertical, somewhat reverse-mirror- image combination of two extruded components like previously-described foundation component 32a in Fig. 10.
- Elongate stabilizer bars in appropriate clusters of bars are provided for the wall structures in building 180, and two bars included in this arrangement of stabilizer bars are shown at 190, 192 in Figs. 22, 26 and 27.
- this component is adapted to receive portions of the now-to-be-described arched roof structure 186 which bridges between wall structures 182, 184 in building 180.
- 26 is the presence at locations 196, 198 of securing structure which is provided adjacent the upper ends of stabilizer bars 190, 192, respectively.
- An upper tie plate 202 bridges between connection locations 196, 198 as seen in Fig. 26.
- Also to be noted in Fig. 26, is the presence in the region of securing structure 198 of a trim finishing component 200 which is very much like previously-described trim component 120.
- elongate rafter components 204 which have substantially the same extmded cross-sectional configuration previously-described for rafter component 130.
- Each of these elongate components has its opposite ends receiving the inwardly projecting tubular components such as component 195 pictured in Fig. 26.
- each component 204 Mounted on and distributed at spaced locations along the underside of each component 204 are plural downwardly extending stmts, and appropriate attaching structure, such as that shown generally at 206 in the figures. The specific mounting arrangements provided for these struts is most clearly shown in Figs. 23 and 24. Extending and tensed appropriately between next adjacent struts 206 distributed along a given structure 204 is a crossing arrangement of tensed cables, such as those shown at 208, 210 in Figs. 21 and 22. Between each two adjacent struts along the length of a component 204, cables 208, 210 lie substantially in a common plane which is the plane of Fig. 22 in the drawings.
- cables 208, 210 are only pictured herein in Figs. 21 and 22, but companion cables which play a role orthogonally with respect to cables 208, 210 are shown especially in Figs. 23 and 24 at 214, 216.
- Cables 214, 216 lie in a common plane which, as was just mentioned, is substantially normal to the plane of Fig. 22. These two cables extend between next adjacent stmts that lie in this orthogonal plane, and extend between adjacent stmts that project downwardly from adjacent elongate curved rafter components, such as component 204.
- elongate spanner cables such as the ones shown in cross section at 220 in Figs. 23 and 24.
- Each cable 220 extends through appropriately accommodating eyelets, such as those shown at 222 near the lower extremities of stmts 206, and each such cable generally follows about the same arched curvature that is pictured in Figs. 21 and 22 for roof structure 186.
- eyelets such as those shown at 222 near the lower extremities of stmts 206
- each such cable generally follows about the same arched curvature that is pictured in Figs. 21 and 22 for roof structure 186.
- tumbuckle structure like that shown at 224 in Fig.
- a manner of accomplishing this includes basically securing one side of the overall roof stmcture in a generally flattened condition to the upper reaches of one wall stmcture, followed by the tensing of the spanner cables, like cable 220, to draw the entire structure into the appropriate just-mentioned arch. Any adjustments that are then necessary to ensure appropriate positioning of all of the downwardly- extending stmts. and the cross-connecting cables between these stmts, is then performed as a final stage in properly stabilizing and configuring the arched roof stmcture of this invention.
- horizontal tension struts like stmt 230 shown in Fig. 23, provide lateral stabilization to the various elongate rims of crossed cables which lie in planes in building 180 like the plane of Fig. 23.
- Fig. 28 in the drawings here, illustrated generally at 240 is an organization of production equipment which has been set up on a job site, such as the job site associated with residence 30, to create, on that site, and as needed, all of the actual, extruded, plastic building components required for the complete fabrication of the residence.
- a hopper infeed shown at 242 into which raw source plastic PVC material, typically in pelletized form, is introduced, and fed from this hopper into a single- or plural-auger extruder 244.
- the hopper and extruder are entirely conventional in construction, and are set up in such a fashion that augured, heated, soft extmded PVC material exits the auger part of the system at 246. From the auger equipment, that material enters a die structure 248 which includes, at the operator's selection, one of many appropriately available, selected, building-component extmsion dies drawn from an appropriate library or collection of dies 250.
- the dies in this collection are, of course, especially designed to create components having all of the desired building cross sections, such as those which have been discussed and illustrated herein.
- cooled, extmded building-component material is delivered along a conveyor 256 appropriately to a cross-cutting machine shown generally at 258 which is downstream from chamber 254.
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- Architecture (AREA)
- Physics & Mathematics (AREA)
- Electromagnetism (AREA)
- Civil Engineering (AREA)
- Structural Engineering (AREA)
- Building Environments (AREA)
- Conveying And Assembling Of Building Elements In Situ (AREA)
- Load-Bearing And Curtain Walls (AREA)
- Joining Of Building Structures In Genera (AREA)
Abstract
Description
Claims
Applications Claiming Priority (3)
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WO1986000043A1 (en) * | 1984-06-08 | 1986-01-03 | Austpac Housing Corporation Pty. Limited | Building system and portable masonry plant suitable therefor |
US4688362A (en) * | 1985-04-01 | 1987-08-25 | Constro S.A. | Set of modular building construction elements |
US5247773A (en) * | 1988-11-23 | 1993-09-28 | Weir Richard L | Building structures |
EP0644302A2 (en) * | 1993-09-21 | 1995-03-22 | Klaus Kunststofftechnik GmbH | Building block system |
US5778618A (en) * | 1993-11-26 | 1998-07-14 | Abrams; Ned Hyman | Modular wall unit, system and method for making storage containers and barriers |
Also Published As
Publication number | Publication date |
---|---|
DE60230399D1 (en) | 2009-01-29 |
ATE417771T1 (en) | 2009-01-15 |
US20070193144A1 (en) | 2007-08-23 |
WO2002072403A1 (en) | 2002-09-19 |
US20030009963A1 (en) | 2003-01-16 |
CA2477255A1 (en) | 2002-09-19 |
EP1379421A1 (en) | 2004-01-14 |
US7444782B2 (en) | 2008-11-04 |
EP1379421B1 (en) | 2008-12-17 |
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